This invention relates to a solid oxide fuel cell system comprising at least one longitudinally extending tubular solid oxide fuel cell and a longitudinally extending heater mounted in thermal proximity to the fuel cell to provide heat to the fuel cell during start up and during operation as needed.
This invention relates to a solid oxide fuel cell system comprising at least one longitudinally extending tubular solid oxide fuel cell and a longitudinally extending heater mounted in thermal proximity to the fuel cell to provide heat to the fuel cell during start up and during operation as needed. The heater and fuel cell can be encased within a tubular thermal casing; the inside of the casing defines a first reactant chamber for containing a first reactant, such as oxidant. The fuel cell comprises a ceramic solid state electrolyte layer and inner and outer electrode layers concentrically arranged around and sandwiching the electrolyte layer. The outer electrode layer is fluidly communicable with the first reactant, and the inner electrode layer is fluidly isolated from the first reactant and fluidly communicable with a second reactant, such as fuel.
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What is claimed is: 1. A solid oxide fuel cell system comprising: (a) at least one tubular solid oxide fuel cell comprising a ceramic solid state electrolyte layer and inner and outer electrode layers concentrically arranged around and sandwiching the electrolyte layer, the inner electrode layer fl
What is claimed is: 1. A solid oxide fuel cell system comprising: (a) at least one tubular solid oxide fuel cell comprising a ceramic solid state electrolyte layer and inner and outer electrode layers concentrically arranged around and sandwiching the electrolyte layer, the inner electrode layer fluidly communicable with only one of an oxidant reactant and a fuel reactant, and the outer electrode layer fluidly communicable with only the other of the oxidant and fuel reactants; and (b) a combustion heater fluidly communicable with the oxidant and fuel reactants such that combustion can occur, the heater mounted in sufficient thermal proximity to the fuel cell that the fuel cell can be heated by the combustion to an operating temperature, the heater comprising a porous outer tube and a porous inner tube within the outer tube, an inside of the inner tube defining an inner combustion chamber fluidly communicable with the oxidant and fuel reactants which form a mixture therein, and an annular space between the inner and outer tubes defining an outer combustion chamber in which fuel and oxidant mixture radially permeating through the inner tube is combusted, the outer tube sufficiently porous to enable the fuel and air reactants to pass through the outer tube. 2. A system as claimed in claim 1, further comprising: a tubular thermal casing, the inside of which defines a first reactant chamber that contains the at least one fuel cell and the heater, and can contain the reactant that is fluidly communicable with the outer electrode layer, wherein the pores of the outer tube of the heater are coated with catalytic material effective to combust a mixture of the air and fuel flowing through the outer tube. 3. A solid oxide fuel cell system comprising: (a) at least one tubular solid oxide fuel cell comprising a ceramic solid state electrolyte layer and inner and outer electrode layers concentrically arranged around and sandwiching the electrolyte layer, the inner electrode layer fluidly communicable with only one of an oxidant reactant and a fuel reactant, and the outer electrode layer fluidly communicable with only the other of the oxidant and fuel reactants; (b) a tubular combustion heater, the inside of which contains the at least one fuel cell, the heater fluidly communicable with the oxidant and fuel reactants such that combustion can occur; and (c) a tubular thermal casing, the inside of which defines a first reactant chamber that contains the at least one fuel cell and the heater, wherein the heater and casing are arranged to define an annular chamber therebetween that is fluidly communicable with an air and fuel mixture, and one or both of the heater and casing are coated with catalytic material effective to combust the air and fuel mixture. 4. A system as claimed in claim 3, wherein the inside of the tubular heater defines an oxidant chamber, and the system comprises the at least one fuel cell located within the oxidant chamber. 5. A system as claimed in claim 4 wherein the at least one fuel cell is embedded in a solid state porous foam matrix inside the oxidant chamber. 6. A solid oxide fuel cell system comprising (a) at least one tubular solid oxide fuel cell comprising a ceramic solid state electrolyte layer and inner and outer electrode layers concentrically arranged around and sandwiching the electrolyte layer, the inner electrode layer fluidly communicable with only one of an oxidant reactant and a fuel reactant, and the outer electrode layer fluidly communicable with only the other of the oxidant and fuel reactants; and (b) a combustion heater comprising a first tube, a dense second tube within the first tube, and a porous third tube inside the second tube, an annular space in between the second and third tubes defining a combustion air chamber, and an inside of the third tube defining a combustion fuel chamber, the combustion air chamber fluidly communicable with the oxidant and the combustion fuel chamber fluidly communicable with the fuel, the third tube sufficiently porous to enable the fuel and air reactants to pass through the third tube such that combustion can occur, and an annular space between the first and second tubes defining a reactant heating chamber fluidly communicable with one of the oxidant reactant and the fuel reactant and thermally coupled to the combustion air chamber such that heat generated from the combustion is transferable to the reactant inside the reactant heating chamber. 7. A solid oxide fuel cell system as claimed in claim 6 wherein the combustion fuel chamber is fluidly communicable with the fuel at a higher pressure than the combustion air chamber is fluidly communicable with the oxidant, thereby causing fuel to permeate radially through the third tube and into the combustion air chamber for combusting with the oxidant therein. 8. A solid oxide fuel cell system as claimed in claim 6 wherein the combustion fuel chamber is fluidly communicable with the fuel at a lower pressure than the combustion air chamber is fluidly communicable with the oxidant, thereby causing oxidant to permeate radially through the third tube and into combustion fuel chamber for combusting with the fuel therein. 9. A solid oxide fuel cell system comprising: (a) at least one tubular solid oxide fuel cell comprising a ceramic solid state electrolyte layer and inner and outer electrode layers concentrically arranged around and sandwiching the electrolyte layer, the inner electrode layer fluidly communicable with only one of an oxidant reactant and a fuel reactant, and the outer electrode layer fluidly communicable with only the other of the oxidant and fuel reactants; and (b) a combustion heater comprising a first tube, a dense second tube within the first tube and a porous third tube inside the second tube, an annular space in between the second and third tubes defining a first combustion chamber, and an inside of the third tube defining a second combustion chamber, the first combustion chamber having an exhaust outlet and the second combustion chamber fluidly communicable with the fuel and oxidant, the fuel and oxidant forming a mixture therein that permeates radially through the third tube and into the first combustion chamber for combusting, and an annular space between the first and second tubes defining a reactant heating chamber fluidly communicable with one of the reactants and thermally coupled to the first combustion chamber such that heat generated from the combustion is transferable to the reactant inside the reactant chamber. 10. A solid oxide fuel cell system as claimed in claim 9 further comprising an flame igniter in the first combustion chamber and effective to ignite the fuel and oxidant mixture therein for combustion by flame burning. 11. A solid oxide fuel cell system as claimed in claim 9 wherein the pores of the third tube are coated with a catalytic material sufficient to catalytically combust the oxidant and fuel mixture passing therethrough. 12. A system as claimed in claim 1 further comprising a flame igniter in the outer combustion chamber and effective to ignite the fuel and oxidant mixture therein for combustion by flame burning. 13. A system as claimed in claim 1 wherein the pores of the inner tube are coated with a catalytic material sufficient to catalytically combust the oxidant and fuel mixture passing therethrough. 14. A system as claimed in claim 2 further comprising a tubular flame arrestor surrounding the heater, the flame arrestor having pores or perforations with a maximum size that is smaller than the quenching diameter of the fuel. 15. A system as claimed in claim 4 further comprising a porous flame arrestor located in the annular chamber and having a maximum pore size smaller than the quenching diameter of the fuel-air mixture flowing through the annular chamber. 16. A system as claimed in claim 15 wherein the flame arrestor is a porous or perforated cylindrical layer located in the annular chamber such that a pair of annular compartments are defined on either side of the cylindrical layer, wherein one compartment is large enough to receive an air/fuel mixture and distribute the mixture uniformly through the cylindrical layer, and the other compartment has a thickness large enough for flames to form therein. 17. A system as claimed in claim 4 further comprising a cylindrical porous catalytic layer located inside the annular chamber such that a pair of annular compartments are defined on either side of the layer and composed of a porous material with pores coated with catalytic material that promotes combustion of a fuel/air mixture in the annular chamber. 18. A system as claimed in claim 2 wherein the heater further comprises an electric resistive element that generates sufficient heat to heat the catalytic material to an operating temperature. 19. A system as claimed in claim 2 wherein the heater comprises a flame burner fluidly communicable with the air and the fuel and operable to ignite the air and fuel to generate a flame and sufficient heat to heat the catalytic material to an operating temperature. 20. A solid oxide fuel cell system as claimed in claim 10 wherein the pores of the third tube are coated with a catalytic material sufficient to catalytically combust the oxidant and fuel mixture passing therethrough. 21. A system as claimed in claim 12 wherein the pores of the inner tube are coated with a catalytic material sufficient to catalytically combust the oxidant and fuel mixture passing therethrough. 22. A system as claimed in claim 1 wherein the heater is tubular and is at least partly filled with a porous flame arrestor that has a maximum pore size that is smaller than the quenching diameter of the fuel. 23. A system as claimed in claim 1 wherein the heater comprises a flame burner fluidly communicable with the air and the fuel and operable to ignite the air and fuel to generate a flame and sufficient heat to heat the catalytic material to an operating temperature.
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